Symplectic sum

Last updated February 26, 2019

In mathematics, specifically in symplectic geometry, the symplectic sum is a geometric modification on symplectic manifolds, which glues two given manifolds into a single new one. It is a symplectic version of connected summation along a submanifold, often called a fiber sum.

Mathematics includes the study of such topics as quantity, structure, space, and change.

Symplectic geometry is a branch of differential geometry and differential topology that studies symplectic manifolds; that is, differentiable manifolds equipped with a closed, nondegenerate 2-form. Symplectic geometry has its origins in the Hamiltonian formulation of classical mechanics where the phase space of certain classical systems takes on the structure of a symplectic manifold.

In mathematics, a symplectic manifold is a smooth manifold, M, equipped with a closed nondegenerate differential 2-form, ω, called the symplectic form. The study of symplectic manifolds is called symplectic geometry or symplectic topology. Symplectic manifolds arise naturally in abstract formulations of classical mechanics and analytical mechanics as the cotangent bundles of manifolds. For example, in the Hamiltonian formulation of classical mechanics, which provides one of the major motivations for the field, the set of all possible configurations of a system is modeled as a manifold, and this manifold's cotangent bundle describes the phase space of the system.

In mathematics, specifically in symplectic geometry, the symplectic cut is a geometric modification on symplectic manifolds. Its effect is to decompose a given manifold into two pieces. There is an inverse operation, the symplectic sum, that glues two manifolds together into one. The symplectic cut can also be viewed as a generalization of symplectic blow up. The cut was introduced in 1995 by Eugene Lerman, who used it to study the symplectic quotient and other operations on manifolds.

Blowing up in algebraic geometry, a transformation on an algebraic variety or scheme, wherein a closed subvariety is replaced with the space of lines passing through it (in the case of a point, a projective space), commonly used to resolve singularities

In mathematics, blowing up or blowup is a type of geometric transformation which replaces a subspace of a given space with all the directions pointing out of that subspace. For example, the blowup of a point in a plane replaces the point with the projectivized tangent space at that point. The metaphor is that of zooming in on a photograph to enlarge part of the picture, rather than referring to an explosion.

Algebraic geometry is a branch of mathematics, classically studying zeros of multivariate polynomials. Modern algebraic geometry is based on the use of abstract algebraic techniques, mainly from commutative algebra, for solving geometrical problems about these sets of zeros.

The symplectic sum has been used to construct previously unknown families of symplectic manifolds, and to derive relationships among the Gromov–Witten invariants of symplectic manifolds.

In mathematics, specifically in symplectic topology and algebraic geometry, Gromov–Witten (GW) invariants are rational numbers that, in certain situations, count pseudoholomorphic curves meeting prescribed conditions in a given symplectic manifold. The GW invariants may be packaged as a homology or cohomology class in an appropriate space, or as the deformed cup product of quantum cohomology. These invariants have been used to distinguish symplectic manifolds that were previously indistinguishable. They also play a crucial role in closed type IIA string theory. They are named after Mikhail Gromov and Edward Witten.

Definition

Let $M_{1}$ and $M_{2}$ be two symplectic $2n$ -manifolds and $V$ a symplectic $(2n-2)$ -manifold, embedded as a submanifold into both $M_{1}$ and $M_{2}$ via

j_{i}:V\hookrightarrow M_{i},

such that the Euler classes of the normal bundles are opposite:

In mathematics, specifically in algebraic topology, the Euler class is a characteristic class of oriented, real vector bundles. Like other characteristic classes, it measures how "twisted" the vector bundle is. In the case of the tangent bundle of a smooth manifold, it generalizes the classical notion of Euler characteristic. It is named after Leonhard Euler because of this.

In differential geometry, a field of mathematics, a normal bundle is a particular kind of vector bundle, complementary to the tangent bundle, and coming from an embedding.

e(N_{M_{1}}V)=-e(N_{M_{2}}V).

In the 1995 paper that defined the symplectic sum, Robert Gompf proved that for any orientation-reversing isomorphism

Robert Ernest Gompf is an American mathematician specializing in geometric topology.

\psi :N_{M_{1}}V\to N_{M_{2}}V

there is a canonical isotopy class of symplectic structures on the connected sum

In the mathematical subject of topology, an ambient isotopy, also called an h-isotopy, is a kind of continuous distortion of an ambient space, for example a manifold, taking a submanifold to another submanifold. For example in knot theory, one considers two knots the same if one can distort one knot into the other without breaking it. Such a distortion is an example of an ambient isotopy. More precisely, let N and M be manifolds and g and h be embeddings of N in M. A continuous map

(M_{1},V)\#(M_{2},V)

meeting several conditions of compatibility with the summands $M_{i}$ . In other words, the theorem defines a symplectic sum operation whose result is a symplectic manifold, unique up to isotopy.

To produce a well-defined symplectic structure, the connected sum must be performed with special attention paid to the choices of various identifications. Loosely speaking, the isomorphism $\psi$ is composed with an orientation-reversing symplectic involution of the normal bundles of $V$ (or rather their corresponding punctured unit disk bundles); then this composition is used to glue $M_{1}$ to $M_{2}$ along the two copies of $V$ .

Generalizations

In greater generality, the symplectic sum can be performed on a single symplectic manifold $M$ containing two disjoint copies of $V$ , gluing the manifold to itself along the two copies. The preceding description of the sum of two manifolds then corresponds to the special case where $X$ consists of two connected components, each containing a copy of $V$ .

Additionally, the sum can be performed simultaneously on submanifolds $X_{i}\subseteq M_{i}$ of equal dimension and meeting $V$ transversally.

Other generalizations also exist. However, it is not possible to remove the requirement that $V$ be of codimension two in the $M_{i}$ , as the following argument shows.

A symplectic sum along a submanifold of codimension $2k$ requires a symplectic involution of a $2k$ -dimensional annulus. If this involution exists, it can be used to patch two $2k$ -dimensional balls together to form a symplectic $2k$ -dimensional sphere. Because the sphere is a compact manifold, a symplectic form $\omega$ on it induces a nonzero cohomology class

[\omega ]\in H^{2}(\mathbb {S} ^{2k},\mathbb {R} ).

But this second cohomology group is zero unless $2k=2$ . So the symplectic sum is possible only along a submanifold of codimension two.

Identity element

Given $M$ with codimension-two symplectic submanifold $V$ , one may projectively complete the normal bundle of $V$ in $M$ to the $\mathbb {CP} ^{1}$ -bundle

P:=\mathbb {P} (N_{M}V\oplus \mathbb {C} ).

This $P$ contains two canonical copies of $V$ : the zero-section $V_{0}$ , which has normal bundle equal to that of $V$ in $M$ , and the infinity-section $V_{\infty }$ , which has opposite normal bundle. Therefore, one may symplectically sum $(M,V)$ with $(P,V_{\infty })$ ; the result is again $M$ , with $V_{0}$ now playing the role of $V$ :

(M,V)=((M,V)\#(P,V_{\infty }),V_{0}).

So for any particular pair $(M,V)$ there exists an identity element $P$ for the symplectic sum. Such identity elements have been used both in establishing theory and in computations; see below.

Symplectic sum and cut as deformation

It is sometimes profitable to view the symplectic sum as a family of manifolds. In this framework, the given data $M_{1}$ , $M_{2}$ , $V$ , $j_{1}$ , $j_{2}$ , $\psi$ determine a unique smooth $(2n+2)$ -dimensional symplectic manifold $Z$ and a fibration

Z\to D\subseteq \mathbb {C}

in which the central fiber is the singular space

Z_{0}=M_{1}\cup _{V}M_{2}

obtained by joining the summands $M_{i}$ along $V$ , and the generic fiber $Z_{\epsilon }$ is a symplectic sum of the $M_{i}$ . (That is, the generic fibers are all members of the unique isotopy class of the symplectic sum.)

Loosely speaking, one constructs this family as follows. Choose a nonvanishing holomorphic section $\eta$ of the trivial complex line bundle

N_{M_{1}}V\otimes _{\mathbb {C} }N_{M_{2}}V.

Then, in the direct sum

N_{M_{1}}V\oplus N_{M_{2}}V,

with $v_{i}$ representing a normal vector to $V$ in $M_{i}$ , consider the locus of the quadratic equation

v_{1}\otimes v_{2}=\epsilon \eta

for a chosen small $\epsilon \in \mathbb {C}$ . One can glue both $M_{i}\setminus V$ (the summands with $V$ deleted) onto this locus; the result is the symplectic sum $Z_{\epsilon }$ .

As $\epsilon$ varies, the sums $Z_{\epsilon }$ naturally form the family $Z\to D$ described above. The central fiber $Z_{0}$ is the symplectic cut of the generic fiber. So the symplectic sum and cut can be viewed together as a quadratic deformation of symplectic manifolds.

An important example occurs when one of the summands is an identity element $P$ . For then the generic fiber is a symplectic manifold $M$ and the central fiber is $M$ with the normal bundle of $V$ "pinched off at infinity" to form the $\mathbb {CP} ^{1}$ -bundle $P$ . This is analogous to deformation to the normal cone along a smooth divisor $V$ in algebraic geometry. In fact, symplectic treatments of Gromov–Witten theory often use the symplectic sum/cut for "rescaling the target" arguments, while algebro-geometric treatments use deformation to the normal cone for these same arguments.

However, the symplectic sum is not a complex operation in general. The sum of two Kähler manifolds need not be Kähler.

History and applications

The symplectic sum was first clearly defined in 1995 by Robert Gompf. He used it to demonstrate that any finitely presented group appears as the fundamental group of a symplectic four-manifold. Thus the category of symplectic manifolds was shown to be much larger than the category of Kähler manifolds.

Around the same time, Eugene Lerman proposed the symplectic cut as a generalization of symplectic blow up and used it to study the symplectic quotient and other operations on symplectic manifolds.

A number of researchers have subsequently investigated the behavior of pseudoholomorphic curves under symplectic sums, proving various versions of a symplectic sum formula for Gromov–Witten invariants. Such a formula aids computation by allowing one to decompose a given manifold into simpler pieces, whose Gromov–Witten invariants should be easier to compute. Another approach is to use an identity element $P$ to write the manifold $M$ as a symplectic sum

(M,V)=(M,V)\#(P,V_{\infty }).

A formula for the Gromov–Witten invariants of a symplectic sum then yields a recursive formula for the Gromov–Witten invariants of $M$ .

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References

Robert Gompf: A new construction of symplectic manifolds, Annals of Mathematics 142 (1995), 527-595
Dusa McDuff and Dietmar Salamon: Introduction to Symplectic Topology (1998) Oxford Mathematical Monographs, ISBN 0-19-850451-9
Dusa McDuff and Dietmar Salamon: J-Holomorphic Curves and Symplectic Topology (2004) American Mathematical Society Colloquium Publications, ISBN 0-8218-3485-1

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